Na+ influx triggers bleb formation on inner hair cells

Large blebs form rapidly on apical membranes of sensory inner hair cells (IHCs) when the organ of Corti is freshly isolated from adult guinea pigs. Bleb formation had two distinguishable phases. Initially, we identified small particles labeled with fluorescent annexin V; these rapidly coalesced into larger aggregates. After particle aggregation, a single membrane bleb emerged from cuticular plate at the vestigial kinocilium location, eventually reaching approximately 10 microm maximum spherical diameter; blebs this size often detached from IHCs. Development of blebs was associated with elevated concentration of intracellular Na(+); blocking Na(+) influx through mechanotransduction and ATP channels in the apical pole of IHCs or by replacement of Na(+) with N-methyl-D-glucamine prevented Na(+) loading and bleb formation. Depletion of intracellular ATP, blocking cAMP synthesis, inhibition of vesicular transport with brefeldin A, or inhibition of phosphatidylinositol 3-kinase with 2-(4-morpholinyl)-8-phenyl-1(4H)-benzopyran-4-one (LY-294002) significantly reduced bleb formation in the presence of a Na(+) load. Neither the mechanism of blebbing nor the size growth of the IHC blebs was associated with cellular apoptosis or necrosis. Bleb formation was not significantly reduced by disassembling microtubules or decreasing intracellular hydrostatic pressure. Moreover, no polymerized actin was observed in the lumen of blebs. We conclude that IHC bleb formation differs from classic blebbing mechanisms and that IHC blebs arise from imbalance of endocytosis and exocytosis in the apical plasma membrane, linked to Na(+) loading that occurs in vitro.     

Lipid order in hepatocyte plasma membrane blebs during ATP depletion measured by digitized video fluorescence polarization microscopy

Low-light digitized video fluorescence polarization microscopy was used to measure lipid order parameters in plasma membrane blebs of single, cultured rat hepatocytes during ATP depletion with the metabolic inhibitors cyanide and iodoacetic acid. Hepatocytes were labeled on the microscope stage with the plasma membrane probe trimethylammoniumdiphenylhexatriene at successive stages of cell injury. A pair of fluorescence polarization ratio images was obtained from a series of four fluorescence images recorded with a polarizer in the emission path oriented first parallel and then perpendicular to each of two orthogonal excitation light polarization directions. From the polarization ratio images, the lipid order parameter S was determined in individual plasma membrane blebs. Results indicate that the plasma membrane becomes uniformly rigid within a few minutes of the addition of metabolic inhibitors when small surface blebs have formed and ATP levels have fallen by greater than 95%. The measured order parameter of S approximately 0.95 in plasma membrane blebs, compared with S approximately 0.75 in normoxic cell plasma membranes, remained unchanged throughout the course of bleb development and ultimate cell death. These findings demonstrate that significant alteration in hepatocyte plasma membrane structure occurs early in hypoxic cell injury.     

LIGHT-INDUCED ALTERATIONS IN RETINAL PYRUVATE AND HIGH-ENERGY PHOSPHATES, IN VIVO

—The effect of illumination upon some metabolic substrates of frog retina was investigated in vivo, using conditions of illumination for which electrophysiological correlates in the retina are well defined. Frogs were frozen immediately after illumination, the tissue was processed for quantitative histochemistry, and the compounds were measured fluorometrically. Levels of P-creatine were lower in flash-illuminated retinas than in either dark- or light-adapted retinas. The high-energy phosphates and pyruvate changed rapidly upon exposure to flashing light, then returned towards the original steady-state level, with ATP preceding pyruvate and P-creatine. ATP and P-creatine were primarily concentrated in the bipolar and ganglion cell layers. The energy reserve of the retina was depleted by an enhanced rate of neural activity in vivo. Levels of P-creatine and ATP decreased in only those cellular layers which initiate neural action potentials. These data suggest that the mechanisms of neural excitation are closely coupled to energy and glucose metabolism in the retina.     

Skeletal muscle ATP-sensitive K+ channels recorded from sarcolemmal blebs of split fibers: ATP inhibition is reduced by magnesium and ADP

Summary A new, nonenzymatically treated preparation of amphibian sarcolemmal blebs has been used to study the regulation of skeletal muscle ATP-sensitive K⁺ [K(ATP)] channels.When a frog skeletal muscle fiber is split in half in a Ca²⁺-free relaxing solution, large hemispherical membrane blebs appear spontaneously within minutes without need for Ca²⁺-induced contraction or enzymatic treatment. These blebs readily formed gigaseals with patch pipettes, and excised inside-out patches were found to contain a variety of K⁺ channels. Most prominent were K(ATP) channels similar to those found in the surface membrane of other muscle and nonmuscle cells. These channels were highly selective for K⁺, had a conductance of 53 pS in 140mmK⁺, and were blocked by internal ATP. The presence of these channels in most patches implies that split-fiber blebs are made up, at least in large part, of sarcolemmal membrane.In this preparation, K(ATP) channels could be rapidly and reversibly blocked by glibenclamide (0.1–10 m) in a dose-dependent manner. These channels were sensitive to ATP in the micromolar range in the absence of Mg. This sensitivity was noticeably reduced in the presence of millimolar Mg, most likely because of the ability of Mg²⁺ ions to bind ATP. Our data therefore suggest that free ATP is a much more potent inhibitor of these channels than MgATP. Channel sensitivity to ATP was significantly reduced by ADP in a manner consistent with a competition between ADP, a weak inhibitor, and ATP, a strong inhibitor, for the same inhibitory binding sites.These observations suggest that the mechanisms of nucleotide regulation of skeletal muscle and pancreatic K(ATP) channels are more analogous than previously thought.     

Apoptotic and necrotic blebs in epithelial cells display similar neck diameters but different kinase dependency

Apoptotic and necrotic blebs elicited by H(2)O(2) were compared in terms of dynamics, structure and underlying biochemistry in HeLa cells and Clone 9 cells. Apoptotic blebs appeared in a few minutes and required micromolar peroxide concentrations. Necrotic blebs appeared much later, prior to cell permeabilization, and required millimolar peroxide concentrations. Strikingly, necrotic blebs grew at a constant rate, which was unaffected throughout successive cycles of budding and detachment. At 1 microm diameter, the necks of necrotic and apoptotic blebs were almost identical. ATP depletion was discarded as a major factor for both types of bleb. Inhibition of ROCK-I, MLCK and p38MAPK strongly decreased apoptotic blebbing but had no effect on necrotic blebbing. Taken together, these data suggest the existence of a novel structure of fixed dimensions at the neck of both types of plasma membrane blebs in epithelial cells. However, necrotic blebs can be distinguished from apoptotic blebs in their susceptibility to actomyosin kinase inhibition.     

Glycolytic and oxidative metabolism in relation to retinal function

Measurements of lactate production and ATP concentration in superfused rat retinas were compared with extracellular photoreceptor potentials (Fast PIII). The effect of glucose concentration, oxygen tension, metabolic inhibition, and light were studied. Optimal conditions were achieved with 5-20 mM glucose and oxygen. The isolated retina had a high rate of lactate production and maintained the ATP content of a freshly excised retina, and Fast PIII potentials were similar to in vivo recordings. Small (less than 10%) decreases in aerobic and anaerobic lactate production were observed after illumination of dark-adapted retinas. There were no significant differences in ATP content in dark- and light-adapted retinas. In glucose-free medium, lactate production ceased, and the amplitude of Fast PIII and the level of ATP declined, but the rates of decline were slower in oxygen than in nitrogen. ATP levels were reduced and the amplitude of Fast PIII decreased when respiration was inhibited, and these changes were dependent on glucose concentration. Neither glycolysis alone nor Krebs cycle activity alone maintained the superfused rat retina at an optimal level. Retinal lactate production and utilization of ATP were inhibited by ouabain. Mannose but not galactose or fructose produced lactate and maintained ATP content and Fast PIII. Iodoacetate blocked lactate production and Fast PIII and depleted the retina of ATP. Pyruvate, lactate, and glutamine maintained ATP content and Fast PIII reasonably well (greater than 50%) in the absence of glucose, even in the presence of iodoacetate. addition of glucose, mannose, or 2-deoxyglucose to medium containing pyruvate and iodoacetate abolished Fast PIII and depleted the retina of its ATP. It is suggested that the deleterious effects of these three sugars depend upon their cellular uptake and phosphorylation during the blockade of glycolysis by iodoacetate.     

NAD glucohydrolase from bovine retina

The NAD glycohydrolase activity in the retina is very low compared with the one found in the brain. Therefore the retina extracts ahve a sufficiently high NAD level so that they are able to form "in vitro" lactate from glucose in anaerobiosis in presence of only ATP, Mg++ and glucose. The NAD glycohydrolase has been found in the retina in a great extent in the microsomes.     

Suppression of snake-venom cardiotoxin-induced cardiomyocyte degeneration by blockage of Ca2+ influx or inhibition of non-lysosomal proteinases.

The incubation of 10(5) single neonatal rat cardiomyocytes with 1 microM-cardiotoxin in a bath medium, Tyrode solution in the presence of 1 mM-Ca2+, at 37 degrees C evoked the following chain of events. Firstly, there appeared a latent period of about 10 min during which the cells behaved normally. Neither lactate dehydrogenase nor ATP leaked from the cells. Cytosolic free Ca2+ increased considerably, as measured by the fluorescence intensity of fura-2-Ca2+ complex. At the same time a large portion of endogenous ATP was depleted. Secondly, after the latent period, the cell beating became irregular and eventually stopped. Thirdly, blebs appeared on the cell surface, leading to cell degeneration. If, before the appearance of blebs, the cells were washed with the bath medium exhaustively or incubated in the presence of the toxin antibody, cytosolic free Ca2+ and endogenous ATP returned to normal levels and cells resumed regular beating. Preincubation of the cells with 3.75 microM-flunarizine or 3.75 microM-diltiazem (both are Ca2+ antagonists), or 1.5 microM-fura-2 acetoxymethyl ester (a chelate for Ca2+), or 200 microM-leupeptin or 50 microM-antipain (both are proteinase inhibitors) considerably suppressed the toxin's ability to degenerate the cells. On the other hand, lysosomal proteinase inhibitor, autophage inhibitor, serine proteinase inhibitor, phospholipase inhibitor and calmodulin antagonist did not inhibit the toxin's activity. The results suggest that the toxin may act on the extracellular surface of intact cardiomyocytes to increase cytosolic free Ca2+. The subsequent cell degeneration may result from the activation of a Ca2+-dependent non-lysosomal proteolytic system.     

Light-induced changes in energy metabolites, guanine nucleotides, and guanylate cyclase within frog retinal layers

Freeze-dried sections were prepared from retinas of frogs which were dark-adapted or exposed to varying periods of light. Samples of the discrete layers were dissected, weighed, and analyzed for energy metabolites, guanylate compounds, and the enzyme guanylate cyclase. ATP and P-creatine were measured in both dark- and light-adapted retinas. There was a gradient in ATP and P-creatine levels in dark-adapted retinas, with the lower concentrations in the photoreceptors, and increasing concentrations in the inner retina. After light adaptation, concentrations increased, an observation which supports the concept that transmitter release occurs in the dark and ceases in the light. The sum of GTP plus GDP, GDP, and cyclic GMP were analyzed in dark-adapted retinas and after exposure to 2 min or 2 h of room light. GDP was rather uniformly distributed in the retinal layers, was increased by 2 min of light in all layers but the outer nuclear, and remained elevated at 2 h in the inner retina. GTP values showed a marked localization in the outer nuclear layer, which increased after 2 min or 2 h of illumination; in all other layers GTP was decreased by light. Cyclic GMP in the dark was highest in the photoreceptor cells, decreasing to one-third after 2 min of light; there were significant increases in the outer plexiform and inner nuclear layers at this time. Cyclic GMP remained low in the photoreceptor cells even after 2 h of light, while the inner layers returned to dark values. Guanylate cyclase, like cyclic GMP, was largely confined to the photoreceptor cells and showed a maximal increase after 2 min of light exposure.     

Nuclear fragility,blaming the blebs

Although textbook pictures depict the cell nucleus as a simple ovoid object, it is now clear that it adopts a large variety of shapes in tissues. When cells deform, because of cell crowding or migration through dense matrices, the nucleus is subjected to large constraints that alter its shape. In this review, we discuss recent studies related to nuclear fragility, focusing on the surprising finding that the nuclear envelope can form blebs. Contrary to the better-known plasma membrane blebs, nuclear blebs are unstable and almost systematically lead to nuclear envelope opening and uncontrolled nucleocytoplasmic mixing. They expand, burst, and repair repeatedly when the nucleus is strongly deformed. Although blebs are a major source of nuclear instability, they are poorly understood so far, which calls for more in-depth studies of these structures.     

Cytosolic-free Ca2+ and cell killing in hepatoma 1c1c7 cells exposed to chemical anoxia

Exposure of cultured hepatoma 1c1c7 cells to KCN and iodoacetate, to produce chemical anoxia, caused a rapid and sustained increase in cytosolic-free Ca2+ concentration, which was associated with depletion of intracellular ATP and glutathione. These changes occurred before the loss of cell viability and were accompanied by the appearance of plasma membrane blebs. Pretreatment of the cells with the Ca2+ chelators Quin 2 or BAPTA markedly delayed both the onset of blebbing and loss of cell viability, but did not affect KCN- and iodoacetate-induced loss of ATP and glutathione. Together, these results strongly suggest that a sustained increase in cytosolic Ca2+ concentration plays an important role in killing of hepatoma cells by chemical anoxia.     

Adenosine in vertebrate retina: Localization,receptor characterization,and function

1. The uptake of [3H] adenosine into specific populations of cells in the inner retina has been demonstrated. In mammalian retina, the exogenous adenosine that is transported into cells is phosphorylated, thereby maintaining a gradient for transport of the purine into the cell. 2. Endogenous stores of adenosine have been demonstrated by localization of cells that are labeled for adenosine-like immunoreactivity. In the rabbit retina, certain of these cells, the displaced cholinergic, GABAergic amacrine cells, are also labeled for adenosine. 3. Purines are tonically released from dark-adapted rabbit retinas and cultured embryonic chick retinal neurons. Release is significantly increased with K+ and neurotransmitters. The evoked release consists of adenosine, ATP, and purine metabolites, and while a portion of this release is Ca2+ dependent, one other component may occur via the bidirectional purine nucleoside transporter. 4. Differential distributions of certain enzymes involved in purine metabolism have also been localized to the inner retina. 5. Heterogeneous distributions of the two subtypes of adenosine receptors, A1 and A2, have been demonstrated in the mammalian retina. Coupling of receptors to adenylate cyclase has also been demonstrated. 6. Adenosine A1 receptor agonists significantly inhibit the K(+)-stimulated release of [3H]-acetylcholine from the rabbit retina, suggesting that endogenous adenosine may modulate the light-evoked or tonic release of ACh.     

ATP released via gap junction hemichannels from the pigment epithelium regulates neural retinal progenitor proliferation

The retinal pigment epithelium (RPE) plays an essential role in the normal development of the underlying neural retina, but the mechanisms by which this regulation occurs are largely unknown. Ca2+ transients, induced by the neurotransmitter ATP acting on purinergic receptors, both increase proliferation and stimulate DNA synthesis in neural retinal progenitor cells. Here, we show that the RPE regulates proliferation in the underlying neural retina by the release of a soluble factor and identify that factor as ATP. Further, we show that this ATP is released by efflux through gap junction connexin 43 hemichannels, the opening of which is evoked by spontaneous elevations of Ca2+ in trigger cells in the RPE. This release mechanism is localized within the RPE cells to the membranes facing the neural retina, a location ideally positioned to influence neural retinal development. ATP released from RPE hemichannels speeds both cell division and proliferation in the neural retina.     

Freeze-fracturing and surface labelling of embryonic neural retina cells

Freeze-fracturing of dissociated and aggregating neural retina cells from 7-day chick embryos revealed on the inner faces (PF) of the cell membrane numerous particles 6–20 nm in size. In contrast, the PF faces of blebs and some of the lobopodia that project from the cell surface were practically devoid of such particles. However, the elongated filopodia that abound on these cells showed numerous particles on their PF faces. These regional differences in the distribution of particles on PF faces of these cells are interpreted as reflecting membrane activity that leads to the formation of blebs and lobopodia. The frequent presence of “pits” at the basis of blebs and lobopodia is described. It is suggested that the “pits” are associated with the formation of these membrane projections; they may represent anchoring sites for microfilaments and for microtubules involved in the dynamic structure of the cell surface. ConA-binding sites on these cells were studied by scanning electron microscopy, using labeling with hemocyanin. The distribution of these sites on different regions of the cell surface coincided with the regional differences in the distribution of the inner membrane particles.     

The retinal rod outer segment of the frog: detachment, isolation, phosphorus fractions and enzyme activity

Frog retinal rod outer segments were detached from dark adapted retinas by (1) agitation in frog Ringer's solution or (2) by crushing between two glass surfaces. The resulting suspensions were further purified by low and high speed centrifugation procedures in Ficoll density gradients. The density of the outer segments in Ficoll solutions was found to be 1.09. The large frog outer segments, unlike bovine outer segments, are not readily separated from nuclei, which were estimated to comprise 2.6–8% of the material, based on DNA analyses. The RNA/DNA ratio was 0.4–0.5, like that of neuronal nuclei. Representative enzymes of glycolysis (lactic dehydrogenase and glyceraldehyde phosphate dehydrogenase), phosphogluconate oxidation (glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase), the citric acid cycle (malic dehydrogenase) and ATP degradation (ATPase) were assayed. A major part of the malic dehydrogenase activity was probably due to inner segments attached to some of the outer segments. Glyceraldehyde phosphate dehydrogenase and glucose-6-phosphate dehydrogenase (but not lactic dehydrogenase) activities were lower in detached outer segments purified on Ficoll gradients than in samples of outer segment layer microdissected from freeze-dried sections of frog retina, as well as in whole retina. The data suggest that the activities of all the enzymes studied are intrinsically low in rod outer segments.     

Potentiation of oxidative cell injury in hepatocytes which have accumulated Ca2+

Incubation of freshly isolated rat hepatocytes with exogenous ATP, but not with succinate, resulted in intracellular Ca2+ accumulation which was partly prevented when the inhibitor of mitochondrial Ca2+ sequestration, ruthenium red, was also present in the medium. Although the bulk of the accumulated Ca2+ was sequestered by the mitochondria, formation of surface blebs and stimulation of phosphorylase alpha activity during incubation of the hepatocytes with ATP indicate that this treatment was also associated with an increase in cytosolic free Ca2+ concentration. When hepatocytes loaded with Ca2+ by preincubation with ATP were exposed to either 2-methyl-1,4-naphthoquinone or t-butyl hydroperoxide, the cytotoxicity of both agents was markedly potentiated. Our results suggest that ATP-induced Ca2+ accumulation in hepatocytes is not due to contamination of the cell suspension with damaged cells or free intracellular organelles and that the intracellular Ca2+ concentration can affect the response to toxic agents.     

ATP-generating glycolytic substrates prevent N-nitrosofenfluramine-induced cytotoxicity in isolated rat hepatocytes

The relationship between cytotoxicity induced by N-nitrosofenfluramine and mitochondrial or glycolytic adenosine triphosphate (ATP) synthesis-dependent intracellular bioenergetics was studied in isolated rat hepatocytes. The supplementation of fructose, an ATP-generating glycolytic substrate, to hepatocyte suspensions prevented N-nitrosofenfluramine-induced cell injury accompanied by the formation of cell blebs, abrupt loss of intracellular ATP and reduced glutathione and mitochondrial membrane potential (DeltaPsi), and the accumulation of oxidized glutathione and malondialdehyde, indicating lipid peroxidation, during a 2h incubation period. Fructose (1-20mM) resulted in concentration-dependent protection against the cytotoxicity of N-nitrosofenfluramine at a concentration of 0.6mM, a low toxic dose. Pretreatment with xylitol, another glycolytic substrate, at concentration of 15mM also prevented the cytotoxicity caused by the nitroso compound, but neither glucose nor sucrose exhibited protective effects. In addition, fructose inhibited N-nitrosofenfluramine (0.5 and 0.6mM)-induced DNA damage, as evaluated in the comet assay, indicating that nuclei as well as mitochondria are target sites of the compound. These results indicate that (a) the onset of N-nitrosofenfluramine-induced cytotoxicity in rat hepatocytes is linked to mitochondrial failure, and that (b) the insufficient supply of ATP in turn limits the activities of all energy-requiring reactions and consequently leads to acute cell death.     

Cell surface changes and enzyme release during hypoxia and reoxygenation in the isolated, perfused rat liver

We examined the effects of hypoxia and reoxygenation in isolated, perfused rat livers. Hypoxia induced by a low rate of perfusion led to near anoxia confined to centrilobular regions of the liver lobule. Periportal regions remained normoxic. Within 15 min, anoxic centrilobular hepatocytes developed surface blebs that projected into sinusoids through endothelial fenestrations. Periportal hepatocytes were unaffected. Both scanning and transmission electron microscopy suggested that blebs developed by transformation of preexisting microvilli. Upon reoxygenation by restoration of a high rate of perfusion, blebs disappeared. Other changes included marked shrinkage of hepatocytes, enlargement of sinusoids, and dilation of sinusoidal fenestrations. There was also an abrupt increase in the release of lactate dehydrogenase and protein after reoxygenation, and cytoplasmic fragments corresponding in size and shape to blebs were recovered by filtration of the effluent perfusate. We also studied phalloidin and cytochalasin D, agents that disrupt the cytoskeleton. Both substances at micromolar concentrations caused rapid and profound alterations of cell surface topography. We conclude that hepatic tissue is quite vulnerable to hypoxic injury. The morphological expression of hypoxic injury seems mediated by changes in the cortical cytoskeleton. Reoxygenation causes disappearance of blebs and paradoxically causes disruption of cellular volume control and release of blebs as cytoplasmic fragments. Such cytoplasmic shedding provides a mechanism for selective release of hepatic enzymes by injured liver tissue.     

The effect of cytoplasmic K+ on the activity of the Na+/K(+)-ATPase.

Experiments with the reconstituted (Na+ + K+)-ATPase show that besides the ATP-dependent cytoplasmic Na(+)-K+ competition for Na+ activation there is a high affinity inhibitory effect of cytoplasmic K+. In contrast to the high affinity K+ inhibition seen with the unsided preparation at a low ATP especially at a low temperature, the high affinity inhibition by cytoplasmic K+ does not disappear when the ATP concentration an-or the temperature is increased. The high affinity inhibition by cytoplasmic K+ is also observed with Cs+, Li+ or K+ as the extracellular cation, but the fractional inhibition is much less pronounced than with Na+ as the extracellular cation. The results suggest that either there are two populations of enzyme, one with the normal ATP dependent cytoplasmic Na(+)-K+ competition, and another which due to the preparative procedure has lost this ATP sensitivity. Or that the normal enzyme has two pathways for the transition from E2-P to E1ATP. One on which the enzyme with the translocated ion binds cytoplasmic K+ with a high affinity but not ATP, and another on which ATP is bound but not K+. A kinetic model which can accommodate this is suggested.     

Calcium dependence of bleb formation and cell death in hepatocytes

Calcium dependence of bleb formation and cell death was evaluated in rat hepatocytes following ATP depletion by metabolic inhibition with KCN and iodoacetate ('chemical hypoxia'). Cytosolic free Ca2+ was measured in single cells by ratio imaging of Fura-2 fluorescence using multiparameter digitized video microscopy. Cells formed surface blebs within 10 to 20 minutes after chemical hypoxia and most cells lost viability within an hour. An increase of cytosolic free Ca2+ was not required for bleb formation to occur. One to a few minutes prior to the onset of cell death, free Ca2+ increased rapidly in high Ca2+ buffer (1.2 mM) but not in low Ca2+ buffer (less than 1 microM). In either buffer, the rate of cell killing was the same. As the onset of cell death was approached in both high and low Ca2+ buffers, Fura-2 began to leak from the cells at an accelerating rate indicating rapidly increasing plasma membrane permeability. In high Ca2+ buffer, cytosolic free Ca2+ increased in parallel with dye leakage. No regional changes in cytosolic free Ca2+ were observed during this metastable period of increased membrane permeability. In many experiments, actual rupture of cell surface blebs could be observed which led to micron-size discontinuities of the cell surface and cell death. We conclude that a metastable period characterized by increasing plasma membrane permeability marked the onset of cell death in cultured hepatocytes which culminated in rupture of a cell surface bleb. An increase of cytosolic free Ca2+ was not required for the metastable state to develop or cell death to occur.